JP6909505B2 - Code bushing - Google Patents

Description

The present invention relates to a cord bushing that is attached in a tubular shape to a hole provided in a wall, a cord is passed through the cylinder, and the cord is pulled out from one surface of the wall to the other surface.

When pulling the cord from one side of the wall to the other, a tubular cord bushing is attached to the through hole to prevent the cord from being damaged by the through hole in the wall and inside the cord bushing. The code is passed through. Some such cord bushings include an inner cylinder and an outer cylinder. The inner cylinder is configured so that it can be inserted into the through hole. The inner cylinder is configured so that it penetrates the wall and the tip penetrates from the surface opposite to the wall surface into which the inner cylinder is inserted. The outer cylinder is configured to be attached to the inner cylinder whose tip penetrates from the wall surface from the surface opposite to the wall surface into which the inner cylinder is inserted. Further, the cord bushing is configured to sandwich the wall between the inner cylinder and the outer cylinder. Since the wall thickness in which such a cord bushing is used varies, there is a demand for a cord bushing that can handle any wall thickness. As a tube capable of penetrating a wall of various thicknesses to protect a cord, for example, a wall penetrating sleeve described in Patent Document 1 is known.

The wall-penetrating sleeve described in Patent Document 1 includes an inner cylinder provided with a plurality of engaged concave portions and an outer cylinder provided with an engaging convex portion attached to the inner cylinder. A plurality of engaged recesses are formed along the circumference of the inner cylinder, and are provided at a plurality of positions having different distances from one tip of the inner cylinder. The engaging convex portion is configured to gradually engage with the engaged concave portion having a different distance from one tip of the inner cylinder. As a result, the combination of the engaged convex portion and the engaged concave portion to be engaged is changed stepwise, so that the relative positions of the outer cylinder and the inner cylinder can be changed stepwise. That is, such a wall-penetrating sleeve can be adapted to various wall thicknesses by adjusting the distance from the tip of the inner cylinder opposite to the side inserted into the outer cylinder to the outer cylinder. Is possible.

Japanese Unexamined Patent Publication No. 2010-127321

However, in the wall-penetrating sleeve described in Patent Document 1, the relative position between the outer cylinder and the inner cylinder is determined by the distance provided with the engaged recesses. Therefore, the length of the distance from the tip of the inner cylinder opposite to the side inserted into the outer cylinder to the outer cylinder does not always match the thickness of the wall. That is, when an attempt is made to sandwich the wall between one end side of the outer cylinder and one end side of the inner cylinder of the wall-penetrating sleeve described in Patent Document 1, a gap is generated between the outer cylinder and the wall and between the wall and the inner cylinder. There was a problem that it could be stored.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a cord bushing capable of sandwiching a wall by reducing a gap regardless of the thickness of the wall.

In order to achieve this object, the cord bushing according to claim 1 is attached to a hole provided in the wall in a tubular shape, and a cord is passed through the cylinder to separate the first space from the first space separated by the wall. It has an outer cylinder that pulls out the cord between the two spaces and has a first contact means that contacts one surface of the wall, and a second contact means that contacts the other surface of the wall. The outer cylinder includes a plurality of first contact means, and an inner cylinder formed so as to be inserted into the outer cylinder so that the wall is sandwiched between the first contact means and the second contact means. A second hooking means provided with a hooking means, the inner cylinder can be paired with one of the first hooking means, and the outer cylinder and the inner cylinder can be hooked in a direction opposite to the insertion direction. The cord bushing is provided by changing the combination of the first hooking means and the second hooking means for hooking while inserting the inner cylinder relative to the outer cylinder. The wall can be sandwiched by narrowing the distance between the first contact means and the second contact means, and at least a pair of the first hooking means and the second hooking means are hooked. In this case, there is a second hooking means and a non-hooking first hooking means, and the non-hooking first hooking means can be hooked with the first hooking means on the side of the second contacting means. The distance to the second hooking means in the above is the non-hooking second hooking means on the side of the second contacting means that can be hooked with the first hooking means. The first hooking means and the second hooking means are arranged so that there is at least one non-hooking first hooking means that is shorter than the distance to the means. The cylinder referred to here is a concept that includes not only a cylinder but also a square cylinder.

The code bushing according to claim 2 is the code bushing according to claim 1, wherein at least one of the first contact means and the second contact means includes elastic means, and the elastic means includes the first contact means and the first contact means. it is obtained shall elastically deformed in contact with the wall when sandwiching the wall by a second contact means.

The code bushing according to claim 3 is the code bushing according to claim 1 or 2, wherein the inner cylinder can penetrate through the hole provided in the wall from the second space, and the second contact means. Is configured so that the second hooking means appears on the first space side when is in contact with the wall on the second space side, and the outer cylinder is said on the first space side. The inner cylinder is relatively inserted, and the second contact means in contact with the wall on the second space side and the first contact means in contact with the wall on the first space side are used. Hold the wall.

The code bushing according to claim 4 is the code bushing according to any one of claims 1 to 3, wherein the first hooking means is on a straight line in the insertion direction passing through the first hooking means. The first hooking means is configured to be nonexistent.

According to the code bushing according to claim 1, the following effects are obtained. That is, the cord bushing according to claim 1, has an outer cylinder and an inner cylinder, is attached in a tubular shape to a hole provided in the wall, passes the cord through the cylinder, and is partitioned by the wall. It pulls out the code between the space and the second space. The inner cylinder is relatively inserted into the outer cylinder. By the first contact means, the outer cylinder comes into contact with one surface of the wall. By the second contact means, the inner cylinder comes into contact with the other surface of the wall. The wall is sandwiched by the outer cylinder and the inner cylinder sandwiching both sides of the wall. At this time, one of the plurality of first hooking means on the outer cylinder is paired with one of the plurality of second hooking means on the inner cylinder, so that the outer cylinder and the inner cylinder are hooked in the opposite direction of the insertion direction. Stop. This limits the movement in the direction in which the distance between the first contact means and the second contact means increases. While inserting the inner cylinder relative to the outer cylinder, the combination of the first hooking means and the second hooking means to be hooked is changed, and the distance between the first contacting means and the second contacting means is changed. By narrowing it, the wall is sandwiched. Then, when at least a pair of the first hooking means and the second hooking means are hooked, at least one first hooking means is not hooked with the second hooking means. Among the non-hooking first hooking means, from the non-hooking first hooking means to the first hooking means and the second hooking means on the side of the second contacting means that can be hooked. There is at least one distance that is shorter than the distance from the first hooking means that has been hooked to the second hooking means that is on the side of the first hooking means and the second contacting means that can be hooked. As a result, when the inner cylinder is relatively inserted into the outer cylinder, the first hooking means currently hooked is the second hooking means on the side of the first hooking means and the second contacting means that can be hooked. Prior to being hooked by the means, the non-hooking first hooking means is hooked on the first hooking means and the second hooking means on the side of the second contacting means that can be hooked. Therefore, the relative positions of the outer cylinder and the inner cylinder that sandwich the wall can be changed little by little. Therefore, the gap between the outer cylinder and the wall, and the gap between the wall and the inner cylinder, which occur when the first contact means and the second contact means are brought as close as possible to sandwich the wall between the outer cylinder and the inner cylinder. The gap can be made extremely small. Therefore, regardless of the thickness of the wall, there is an effect that the gap between the outer cylinder and the wall and the gap between the wall and the inner cylinder can be reduced to sandwich the wall.

According to the code bushing according to the second aspect, in addition to the effect of the code bushing according to the first aspect, the following effect is exhibited. That is, at least one of the first contact means and the second contact means has elastic means. The elastic means, Ru obtained when clamping the wall with a first contact means and second contact means elastic deformation occurs. The elastic means in which the elastic deformation occurs presses at least one of the first contact means and the second contact means against the wall according to the law of action and reaction. This has the effect that the cord bushing can be mounted on the wall without wobbling.

According to the code bushing according to the third aspect, in addition to the effect of the code bushing according to the first or second aspect, the following effect is exhibited. That is, the inner cylinder is inserted from the second space so as to penetrate the hole provided in the wall. Then, when the second contact means is in contact with the wall on the second space side, the second hooking means appears on the first space side, and the inner cylinder is relative to the outer cylinder on the first space side. Will be inserted. The second contact means comes into contact with the wall on the second space side, and the first contact means comes into contact with the wall on the first space side, so that the wall is sandwiched. This has the effect of providing a cord bushing that can handle walls of various thicknesses simply by preparing an inner cylinder that can penetrate the wall.

According to the code bushing according to claim 4, in addition to the effect of the code bushing according to any one of claims 1 to 3, the following effect is exhibited. That is, the other first hooking means does not exist on the straight line in the insertion direction passing through the first hooking means. If the other first hooking means exists on a straight line in the insertion direction passing through the first first hooking means, the one first hooking means and the other first hooking means are separated from each other at a narrow interval. It needs to be provided, which makes industrial processing extremely difficult. On the other hand, by configuring the other first hooking means so as not to exist on a straight line in the insertion direction passing through the first first hooking means, the first hooking means is provided at narrow intervals. No need. This facilitates industrial processing, which has the effect of reducing the occurrence of defective products and increasing the production efficiency of cord bushings.

(A) is a perspective view of the entire cord bushing according to the first embodiment of the present invention, and (b) is a right side view of the entire cord bushing. It is sectional drawing which cut the inner cylinder in the left-right direction. It is a perspective view of an outer cylinder. It is sectional drawing of the cord bushing 10 when the 2nd claw of the outer cylinder of the outer cylinder is cut in the IV direction in the state which the 7th claw of the inner cylinder of the inner cylinder is hooked. (A) is a diagram schematically showing a state in which the second claw of the outer cylinder is hooked on the inner cylinder, and (b) is a state in which the first claw of the outer cylinder is hooked on the inner cylinder. Is a diagram schematically showing. (A) is a diagram schematically showing a state in which the second claw of the outer cylinder hooks the inner cylinder and the contact surface of the outer cylinder is in contact with the wall, and FIG. It is the figure which showed typically the state in which the claw hooks the inner cylinder, and the contact surface of the outer cylinder is in contact with a wall. (A) is a diagram schematically showing a state in which the second claw of the outer cylinder is hooked on the inner cylinder in the cord bushing according to the second embodiment of the present invention, and (b) is a diagram schematically showing a state in which the second claw of the outer cylinder is hooked. It is a figure which showed typically the state which the 1st claw is hooking an inner cylinder. (A) is a diagram schematically showing a state in which the third claw of the outer cylinder is hooked on the inner cylinder in the cord bushing according to the third embodiment of the present invention, and (b) is a diagram schematically showing a state in which the third claw of the outer cylinder is hooked. It is a figure which showed typically the state which the 2nd claw hooked an inner cylinder, and (c) is the figure which typically showed the state which the 1st claw of an outer cylinder hooked an inner cylinder. Is. (A) is a diagram schematically showing a state in which the third claw of the outer cylinder is hooked on the inner cylinder in the cord bushing according to the fourth embodiment of the present invention, and (b) is a diagram schematically showing a state in which the third claw of the outer cylinder is hooked. It is a figure which showed typically the state which the 2nd claw hooked an inner cylinder, and (c) is the figure which typically showed the state which the 1st claw of an outer cylinder hooked an inner cylinder. Is.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. First, the outline of the code bushing 10 will be described with reference to FIGS. 1 to 3. FIG. 1A is a perspective view showing the entire cord bushing 10 according to the first embodiment of the present invention, and FIG. 1B is a right side view of the cord bushing 10 (shown in FIG. 1A). FIG. 2 is a cross-sectional view of the inner cylinder 12 cut in the left-right direction, and FIG. 3 is a perspective view of the outer cylinder 11. In this description, for convenience, the direction shown in FIG. 1A is defined as the left-right direction.

The cord bushing 10 includes an outer cylinder 11 and an inner cylinder 12. The cord bushing 10 is attached to the wall by inserting the inner cylinder 12 into the hole provided in the wall and inserting the outer cylinder 11 into the inner cylinder 12 on the wall surface opposite to the wall surface into which the inner cylinder 12 is inserted. The cord is pulled out from one side separated by a wall to the other side. The insertion is a concept of inserting the inner cylinder 12 into the outer cylinder 11 or inserting the outer cylinder 11 into the inner cylinder 12. Further, in the present embodiment, among the spaces partitioned by the wall, the space provided with the outer cylinder 11 is referred to as the first space, and the space on the side where the inner cylinder 12 is inserted into the hole provided in the wall is the second space. It's called space.

The outer cylinder 11 is a member for inserting the inner cylinder 12 into the inner cylinder 12 and hooking the inner cylinder 12 on the wall surface on the first space side opposite to the wall surface on the second space side where the inner cylinder 12 is inserted into the wall. be. The inner cylinder 12 is a member for penetrating the wall and pulling out the cord.

The outer cylinder 11 includes an outer cylinder first claw 30 and an outer cylinder second claw 31. On the other hand, the inner cylinder 12 includes an inner cylinder claw 13. The outer cylinder first claw 30 and the outer cylinder second claw 31 are claws for hooking the outer cylinder 11 to the inner cylinder 12 by hooking the inner cylinder claw 13. The inner cylinder claw 13 is a claw for hooking the inner cylinder 12 on the outer cylinder 11 by being hooked by the outer cylinder first claw 30 or the outer cylinder second claw 31. When the outer cylinder 11 is inserted into the inner cylinder 12, the outer cylinder 1st claw 30 or the outer cylinder second claw 31 hooks the inner cylinder claw 13, so that the outer cylinder 11 hooks the inner cylinder 12. At this time, although the wall is not shown in FIG. 1, the outer cylinder 11 presses the left side of the wall (the wall surface on the first space side), and the inner cylinder 12 presses the right side of the wall (the wall surface on the second space side). Then, the wall will be pinched.

Here, the configuration of the inner cylinder 12 will be described. As shown in FIGS. 1A and 2, the inner cylinder 12 includes an inner cylinder claw 13, a flange 14, an inner cylinder hole 15, and a cylinder 16. An annular flange 14 having an outer diameter larger than the inner diameter of the hole provided in the wall is provided at the right end of the inner cylinder 12. The flange 14 is for contacting the wall surface on the second space side and restricting the inner cylinder 12 from moving further to the left. A cylinder 16 concentric with the flange 14 is provided at a right angle from the flange 14 to the left. The cylinder 16 is a pipe for penetrating a hole provided in the wall. On the outer peripheral surface of the cylinder 16, a plurality of annular inner cylinder claws 13 are provided at equal intervals in parallel with the flange 14. Further, an inner cylinder hole 15 is provided so as to penetrate the flange 14 and the inside of the cylinder 16. The inner cylinder hole 15 is a hole for passing the cord through the cylinder 16.

The outer diameter of the cylinder 16 is smaller than the inner diameter of the outer cylinder hole 33 of the outer cylinder 11 described later, and the cylinder 16 can be passed through the outer cylinder hole 33. As described above, any of the inner cylinder claws 13 provided on the cylinder 16 is hooked by the outer cylinder first claw 30 or the outer cylinder second claw 31 provided on the outer cylinder 11, whereby the inner cylinder 12 Is hooked by the outer cylinder 11. At this time, the relative positions of the outer cylinder 11 and the inner cylinder 12 are changed by changing the combination of the inner cylinder claw 13 to be hooked, the outer cylinder first claw 30, and the outer cylinder second claw 31.

Further, since the outer diameter of the cylinder 16 is smaller than the inner diameter of the hole provided in the wall, the cylinder 16 can be inserted into the hole provided in the wall. The distance from the left end of the cylinder 16 to the flange 14 is such that the cylinder 16 penetrates the hole provided in the wall and is hooked on the outer cylinder 11. Therefore, by passing the cylinder 16 of the inner cylinder 12 through the hole provided in the wall and inserting the outer cylinder 11 into the cylinder 16 protruding from the wall on the first space side, the outer cylinder 11 becomes the inner cylinder. 12 can be hooked.

As shown in FIG. 2, on the outer peripheral surface of the cylinder 16 of the inner cylinder 12, eight serrated inner cylinder claws 13 (inner cylinder first claw 13a to inner cylinder eighth claw 13h) are left and right along the circumference. It is formed at equal intervals in the direction. Each inner cylinder claw 13 is provided so as to intersect the cylinder 16 at a right angle on the flange 14 side and to intersect the cylinder 16 at an acute angle on the left end side.

The inner peripheral surface of the cylinder 16 has a smooth structure having no protrusions or the like. This makes it easier for the cord to pass through when the cord is passed through the cylinder 16. Further, a contact surface 17 is provided on the left surface of the flange 14. The contact surface 17 is a surface for contacting the wall surface on the second space side of the flange 14. Since the contact surface 17 is flat, it can be in close contact with the wall.

Next, the configuration of the outer cylinder 11 will be described. As shown in FIGS. 1A and 3, the outer cylinder 11 has a flat annular cylindrical shape, and has an outer cylinder first claw 30, an outer cylinder second claw 31, a contact surface 32, and an outer cylinder. A cylinder hole 33, a support member 34, and a recess 35 are provided. The outer cylinder hole 33 is a hole for inserting the outer cylinder 11 into the inner cylinder 12. Further, the outer cylinder 11 includes a pair of outer cylinder first claws 30a and 30b at point-symmetrical positions with respect to the center of the circular outer cylinder 11 circle (hereinafter, a pair of outer cylinder first claws 30a and 30b). The claw is called the outer cylinder first claw 30). The outer cylinder 11 includes a pair of outer cylinder second claws 31a and 31b at positions displaced clockwise from the outer cylinder first claws 30a and 30b by about 90 degrees (hereinafter, a pair of outer cylinder first claws 31a and 31b). The two claws are referred to as the outer cylinder second claw 31). The outer cylinder first claw 30 and the outer cylinder second claw 31 are provided with claws protruding from the inner circumference of the annular outer cylinder 11 toward the outer cylinder hole 33.

The outer cylinder first claw 30 and the outer cylinder second claw 31 are provided in pairs at point-symmetrical positions. Therefore, when the outer cylinder 11 hooks the inner cylinder 12, the force from the outer cylinder 11 acts evenly on the inner cylinder 12. Therefore, there is an effect that the outer cylinder 11 can firmly fix the inner cylinder 12.

Further, the outer cylinder 11 is provided with a pair of contact surfaces 32a and 32b at positions displaced clockwise by about 45 degrees from the first claws 30a and 30b of the outer cylinders (hereinafter, the pair of contact surfaces are contact surfaces 32). ). The contact surface 32 is a surface for contacting the wall on the first space side in the outer cylinder 11.

The contact surface 32 is formed in a recess 35 provided on the right bottom surface of the outer cylinder 11 (the surface on the flange 14 side when the cylinder 16 of the inner cylinder 12 is inserted into the outer cylinder hole 33) on the outer peripheral side of the outer cylinder 11. A support member 34 having the characteristics of a leaf spring, which will be described later, projects from the bottom surface on the right side of the outer cylinder 11 and is supported so as to be elastically contactable with the wall surface.

The outer diameter of the outer cylinder 11 is larger than the inner diameter of the hole provided in the wall. Therefore, the outer cylinder 11 cannot be inserted into the hole provided in the wall, and the outer cylinder 11 moves further to the right when the bottom surface on the right side of the outer cylinder 11 is in contact with the wall on the first space side. Can not.

The interval in the insertion direction from the bottom surface on the right side of the outer cylinder 11 to the tip of the claw of the first claw 30a of the outer cylinder, and the insertion direction from the bottom surface on the right side of the outer cylinder 11 to the tip of the claw of the first claw 30b of the outer cylinder. The intervals are equal. Therefore, when the outer cylinder first claw 30a is in the hooked state with any of the inner cylinder first claw 13a to the inner cylinder eighth claw 13h, the outer cylinder first claw 30b is hooked by the outer cylinder first claw 30a. The same inner cylinder claw 13 as used is hooked. That is, the outer cylinder first claws 30a and 30b face each other and hook one inner cylinder claw 13.

Similarly, the distance in the insertion direction from the bottom surface on the right side of the outer cylinder 11 to the tip portion of the claw of the second claw 31a of the outer cylinder, and from the bottom surface on the right side of the outer cylinder 11 to the tip portion of the claw of the second claw 31b of the outer cylinder. The spacing in the insertion direction is equal. Therefore, when the outer cylinder second claw 31a is in the hooked state with any of the inner cylinder first claw 13a to the inner cylinder eighth claw 13h, the outer cylinder second claw 31b is hooked by the outer cylinder second claw 31a. The same inner cylinder claw 13 as used is hooked. That is, the outer cylinder second claws 31a and 31b face each other and hook one inner cylinder claw 13.

On the other hand, the distance in the insertion direction from the bottom surface on the right side of the outer cylinder 11 to the tip portion of the claw of the first claw 30 of the outer cylinder is from the bottom surface on the right side of the outer cylinder 11 to the tip portion of the claw of the second claw 31 of the outer cylinder. It is longer than the interval in the insertion direction of. Details will be described later, but when the outer cylinder first claw 30 is in the hooked state with any one of the inner cylinder first claw 13a to the inner cylinder eighth claw 13h, the outer cylinder second claw 31 is the inner cylinder claw. 13 is also configured so as not to be hooked. On the contrary, when the outer cylinder second claw 31 hooks any one of the inner cylinder first claw 13a to the inner cylinder eighth claw 13h, the outer cylinder first claw 30 is any inner cylinder claw 13. It is configured so that it does not stop.

The outer cylinder first claw 30 and the outer cylinder second claw 31 have a surface provided on the left side of the outer cylinder first claw 30 and the outer cylinder second claw 31 in a direction perpendicular to the inner peripheral surface of the outer cylinder 11. The outer cylinder 1st claw 30 and the outer cylinder 2nd claw 31 have a surface provided on the right side of the outer cylinder 11 in an acute angle with the inner peripheral surface of the outer cylinder 11.

The support member 34 is a member for supporting the contact surface 32 on the outer cylinder 11 so as to be in contact with the wall surface. When the outer cylinder 11 is pushed into the wall side and the wall on the first space side comes into contact with the contact surface 32, the support member 34 is deformed via the contact surface 32. The recess 35 is a space for storing the support member 34 when the support member 34 is elastically deformed.

Next, a state in which the outer cylinder 11 hooks the inner cylinder 12 will be described with reference to FIG. FIG. 4 is a cross-sectional view of the cord bushing 10 when the outer cylinder 2nd claw 31a of the outer cylinder 11 is cut in the IV direction while the inner cylinder 7th claw 13g of the inner cylinder 12 is hooked. In the upper half of FIG. 4, the inner cylinder 12 and the outer cylinder second claw 31a are shown by solid lines, and the state of the outer cylinder first claw 30a at that time is shown by an imaginary line. In the lower half of FIG. 4, the inner cylinder 12 and the outer cylinder first claw 30a are shown by solid lines, and the state of the outer cylinder second claw 31a at that time is shown by an imaginary line.

As described above, the inner cylinder claw 13 is provided so as to intersect the cylinder 16 at a right angle on the flange 14 side and to intersect the cylinder 16 at an acute angle on the left end side. On the other hand, the outer cylinder first claw 30 and the outer cylinder second claw 31 are provided on the left side of the outer cylinder first claw 30 and the outer cylinder second claw 31 in a direction perpendicular to the inner peripheral surface of the outer cylinder 11. The outer cylinder 1st claw 30 and the outer cylinder 2nd claw 31 have an inner peripheral surface of the outer cylinder 11 and a surface provided at an acute angle on the right side.

The outer cylinder 11 is formed by sliding the surface of the inner cylinder claw 13 where the right surface of the outer cylinder first claw 30a and the outer cylinder second claw 31a of the outer cylinder 11 intersects the cylinder 16 at an acute angle. Can be moved from the left end of the to the flange 14 side (insertion direction). On the other hand, the left side surfaces of the outer cylinder first claw 30a and the outer cylinder second claw 31a that intersect the inner peripheral surface of the outer cylinder 11 at right angles face the surface of the inner cylinder claw 13 that intersects the cylinder 16 at right angles. , The inner cylinder 12 is restricted from moving to the right, and the outer cylinder 11 hooks the inner cylinder 12. At this time, since the outer cylinder 11 hooks the inner cylinder 12 and the inner cylinder 12 also hooks the outer cylinder 11, the outer cylinder 11 has the outer cylinder 11 on the left end side (from the flange 14 side of the inner cylinder 12). Restrict movement in the opposite direction of the insertion direction). Therefore, when the outer cylinder 11 is inserted into the inner cylinder 12, the outer cylinder 11 can move in the flange 14 direction (insertion direction), but once the outer cylinder first claw 30a or the outer cylinder second claw 31a is inside. When the cylinder claw 13 is hooked, the outer cylinder 11 cannot return to the left direction (the direction opposite to the insertion direction).

As shown in FIG. 4, when the outer cylinder second claw 31a of the outer cylinder 11 hooks the inner cylinder claw 13 of the inner cylinder 12, the outer cylinder first claw 30a of the outer cylinder 11 is the inner cylinder. The inner cylinder claw 13 of 12 is not hooked and is in a slidable state.

When the outer cylinder 11 moves to the right (insertion direction), the outer cylinder first claw 30a of the outer cylinder 11 hooks the inner cylinder claw 13 of the inner cylinder 12. In that case, the outer cylinder second claw 31a of the outer cylinder 11 is in a slidable state without hooking the inner cylinder claw 13 of the inner cylinder 12.

In this way, when the outer cylinder 11 moves to the right (insertion direction), one of the outer cylinder first claw 30 and the outer cylinder second claw 31 hooks the inner cylinder claw 13, and the other is the inner cylinder claw. It becomes a non-hanging state with 13.

Next, the relationship between the outer cylinder first claw 30, the outer cylinder second claw 31, and the inner cylinder claw 13 will be described with reference to FIG. FIG. 5A is a diagram schematically showing a state in which the outer cylinder second claw 31a is hooked on the inner cylinder fourth claw 13d, and FIG. 5B is a diagram schematically showing a state in which the outer cylinder first claw 30a is hooked. Is a diagram schematically showing a state in which the inner cylinder fourth claw 13d is hooked. In these figures, how the outer cylinder first claw 30a and the outer cylinder second claw 31a are relative to the inner cylinder claw 13 in the insertion direction (direction from the left end of the inner cylinder 12 toward the flange 14). The positional relationship is schematically shown, the inner cylinder 12 and the outer cylinder second claw 31a are shown by a solid line, and the state of the outer cylinder first claw 30a at that time is shown by an imaginary line.

In the present embodiment, the inner cylinder claws 13 are provided at equal intervals at a distance P1. On the other hand, the distance between the outer cylinder first claw 30a and the outer cylinder second claw 31a in the left-right direction (insertion direction) is the distance P2. The relationship between P1 and P2 is expressed by the following equation (1).

P2 = P1 × 1/2 ... (1)

That is, the distance P2 is half of the distance P1. Therefore, as shown in FIG. 5A, when the outer cylinder second claw 31a hooks the inner cylinder fourth claw 13d, the outer cylinder first claw 30a hooks any of the inner cylinder claws 13. Not.

When the outer cylinder 11 is inserted into the inner cylinder 12 from the state of FIG. 5 (a) (the outer cylinder 11 moves in the insertion direction), the outer cylinder 11 and the inner cylinder 12 are in the state of FIG. 5 (b). Move to. That is, the hook of the outer cylinder second claw 31a to the inner cylinder fourth claw 13d is released, and the outer cylinder first claw 31a hooks the inner cylinder third claw 13c before the outer cylinder second claw 31a hooks the inner cylinder third claw 13c. 30a hooks the inner cylinder fourth claw 13d. This is because the outer cylinder second claw 31a needs to move the distance P1 in order to hook the inner cylinder third claw 13c, whereas the outer cylinder first claw 30a moves the inner cylinder fourth claw 13d. This is because it is only necessary to move a distance half the distance P1 (that is, the distance P2) in order to stop the hook.

Similarly, when the outer cylinder 11 is further inserted into the inner cylinder 12 (the outer cylinder 11 moves in the insertion direction), the hook of the outer cylinder 1st claw 30a of the outer cylinder 11 to the inner cylinder 4th claw 13d is released. Therefore, the outer cylinder second claw 31a hooks the inner cylinder third claw 13c before the outer cylinder first claw 30a hooks the inner cylinder third claw 13c. This is because the outer cylinder first claw 30a needs to move the distance P1 in order to hook the inner cylinder third claw 13c, whereas the outer cylinder second claw 31a holds the inner cylinder third claw 13c. This is because it is only necessary to move a distance half the distance P1 (that is, the distance P2) in order to stop the hook. Similarly, thereafter, the outer cylinder 11 hooks the inner cylinder 12 while changing the combination of the inner cylinder claw 13 on which the outer cylinder first claw 30a and the outer cylinder second claw 31a are hooked, and the outer cylinder 11 hooks the inner cylinder 12 at a distance P1. Move in the insertion direction by a distance of 1/2 of.

As a result, the outer cylinder 11 can be moved toward the flange 14 by half the distance P1. Therefore, the cord bushing 10 occurs when the contact surface 32 of the outer cylinder 11 and the contact surface 17 of the inner cylinder 12 are brought as close as possible to each other and the wall is to be sandwiched between the outer cylinder 11 and the inner cylinder 12. There is an effect that the gap between the outer cylinder 11 and the wall surface on the first space side and the gap between the inner cylinder 12 and the wall surface on the second space side can be made extremely small.

By the way, if the outer cylinder second claw 31a is provided on a straight line in the insertion direction passing through the outer cylinder first claw 30a, the outer cylinder first claw 30a and the outer cylinder are provided at intervals that satisfy the above equation (1). In order to provide the second claw 31a on the outer cylinder 11, it is necessary to provide two claws at a narrow interval, which makes industrial processing extremely difficult. In the cord bushing 10 according to the present embodiment, as described above, a pair of outer cylinder second claws 31a and 31b are provided at positions displaced clockwise from the outer cylinder first claws 30a and 30b by about 90 degrees. The outer cylinder second claw 31 is provided so as not to exist on a straight line in the insertion direction passing through the outer cylinder first claw 30. Therefore, the distance in the insertion direction from the bottom surface on the right side of the outer cylinder 11 to the tip portion of the claw of the first claw 30a of the outer cylinder and from the bottom surface on the right side of the outer cylinder 11 to the tip portion of the claw of the second claw 31a of the outer cylinder. There is an effect that the difference from the interval in the insertion direction can be easily adjusted.

Further, according to the present invention, the moving distance in which the outer cylinder 11 moves stepwise can be shortened without narrowing the distance between the inner cylinder claws 13. Therefore, it is not necessary to obtain a high degree of accuracy when the inner cylinder claw 13 is industrially processed. Therefore, the occurrence of defective products can be reduced, and the production efficiency of the cord bushing 10 can be increased.

Next, the operation of the contact surface 32 when the outer cylinder 11 comes into contact with the wall w will be described with reference to FIG. FIG. 6A shows a state in which the outer cylinder second claw 31a of the outer cylinder 11 hooks the inner cylinder fifth claw 13e of the inner cylinder 12 and the contact surface 32a of the outer cylinder 11 is in contact with the wall w. FIG. 6B is a diagram schematically shown, in which the outer cylinder first claw 30a of the outer cylinder 11 hooks the inner cylinder fifth claw 13e of the inner cylinder 12, and the contact surface 32a of the outer cylinder 11 is formed. It is a figure which showed typically the state which is in contact with a wall w. In these figures, the inner cylinder 12, the contact surface 32, the support member 34, and the outer cylinder second claw 31a are shown by solid lines, and the state of the outer cylinder first claw 30a at this time is shown by an imaginary line.

In FIG. 6A, the outer cylinder second claw 31a hooks the inner cylinder fifth claw 13e. The support member 34 is not elastically deformed, and the contact surface 32a is in contact with the wall w on the first space side. Further, the contact surface 17 of the flange 14 is in contact with the wall surface on the second space side opposite to the wall surface on the first space side in contact with the contact surface 32a. At this time, the distance at which the contact surface 32a protrudes from the outer cylinder 11 toward the wall surface on the first space side is the distance Q1.

In FIG. 6B, the outer cylinder 11 approaches the wall surface on the first space side by one step, and the outer cylinder first claw 30a hooks the inner cylinder fifth claw 13e. The support member 34 is elastically deformed by being sandwiched between the outer cylinder 11 and the wall w, and the contact surface 32a is in contact with the wall w. At this time, the distance at which the contact surface 32a protrudes from the outer cylinder 11 toward the wall surface on the first space side is the distance Q2. The relationship between the distance Q1 and the distance Q2 and the above-mentioned distance P2 can be expressed by the following equation (2).

Q1-P2 = Q2 ... (2)

That is, the support member 34 is elastically deformed by the amount (distance P2) that the outer cylinder 11 approaches the wall w side. Then, in a state where the support member 34 is elastically deformed, the outer cylinder first claw 30a hooks the inner cylinder fifth claw 13e, and the contact surface 32a and the contact surface 17 of the inner cylinder 12 come into contact with the wall w. There is. At this time, the support member 34 is elastically deformed by being sandwiched between the outer cylinder 11 and the wall w, and is brought into contact with the outer cylinder first claw 30a while being pushed back to the inner cylinder fifth claw 13e according to the law of action / reaction. The surface 32a is pushed back to the wall w. As a result, when the wall w is to be sandwiched between the outer cylinder 11 and the inner cylinder 12, there is an effect that the cord bushing 10 can be attached to the wall without wobbling.

As described above, according to the cord bushing 10 in the first embodiment, when one of the outer cylinder first claw 30 and the outer cylinder second claw 31 hooks the inner cylinder claw 13, the other is inside. It is in a non-hooking state with the cylinder claw 13. When the outer cylinder 11 is moved in the insertion direction in this state, the inner cylinder claw 13 and the outer cylinder first claw 30 or the outer cylinder second claw 31, which are not hooked, hook the inner cylinder claw 13. The moving distance at this time is half the distance from the hooked outer cylinder first claw 30 or the outer cylinder second claw 31 to the next inner cylinder claw 13 in the insertion direction. As a result, the inner cylinder 12 can be hooked while the outer cylinder 11 is gradually moved toward the flange 14. Therefore, the outer cylinder 11 and the first generated when the contact surface 32 of the outer cylinder 11 and the contact surface 17 of the inner cylinder 12 are brought as close as possible to sandwich the wall between the outer cylinder 11 and the inner cylinder 12. The gap between the wall surface on the 1st space side and the gap between the inner cylinder 12 and the wall surface on the 2nd space side can be made extremely small. Therefore, regardless of the thickness of the wall, the gap between the outer cylinder 11 and the wall surface on the first space side and the gap between the wall surface on the second space side and the inner cylinder 12 can be reduced to sandwich the wall. be.

Further, the inner cylinder 12 is inserted so as to penetrate a hole provided in the wall from the wall surface on the second space side, which is one wall surface. Then, when the contact surface 17 is in contact with the wall surface on the second space side, the inner cylinder claw 13 is placed on the first space side opposite to the wall surface on the second space side into which the inner cylinder 12 is inserted. The outer cylinder 11 is inserted into the inner cylinder 12 on the first space side. At this time, the outer cylinder 11 hooks the inner cylinder 12 while moving toward the flange 14 at half the interval of the inner cylinder claw 13. Then, the contact surface 17 comes into contact with the wall surface on the second space side on the side where the inner cylinder 12 is inserted, and the contact surface 32 is the first space opposite to the wall surface on the second space side where the inner cylinder 12 is inserted. The wall is pinched by contacting the side wall surface. As a result, there is an effect that the cord bushing 10 that can correspond to a wall having various thicknesses can be provided only by preparing the inner cylinder 12 that can penetrate the wall.

Next, the code bushing 10 in the second embodiment will be described with reference to FIG. 7. In the first embodiment, the case where the distance between the outer cylinder first claw 30 and the outer cylinder second claw 31 in the insertion direction is 1/2 of the distance provided by the inner cylinder claw 13 has been described. On the other hand, in the cord bushing 10 of the second embodiment, the distance between the outer cylinder first claw 30 and the outer cylinder second claw 31 in the insertion direction is set to 3/4 of the distance provided with the inner cylinder claw 13. do.

Hereinafter, the code bushing 10 of the second embodiment will be described focusing on the differences from the code bushing 10 of the first embodiment, and the same reference numerals will be given to the same configurations as the code bushing 10 of the first embodiment. And the explanation is omitted.

FIG. 7A is a diagram schematically showing a state in which the outer cylinder second claw 31a is hooked on the inner cylinder 12 in the cord bushing 10 in the second embodiment, and FIG. 7B is a diagram schematically showing a state in which the inner cylinder 12 is hooked. It is a figure which shows typically the state in which the outer cylinder 1st claw 30a is hooking the inner cylinder 12. In these figures, how the outer cylinder first claw 30a and the outer cylinder second claw 31a are relative to the inner cylinder claw 13 in the left-right direction (the direction from the left end of the inner cylinder 12 toward the flange 14). The positional relationship is schematically shown, the inner cylinder 12 and the outer cylinder second claw 31a are shown by a solid line, and the state of the outer cylinder first claw 30a at that time is shown by an imaginary line.

As shown in FIG. 7A, the outer cylinder second claw 31a hooks the inner cylinder third claw 13c. At this time, none of the inner cylinder claws 13 is hooked on the outer cylinder first claw 30a. Further, as described above, the distance between the outer cylinder first claw 30a and the outer cylinder second claw 31a in the insertion direction is 3/4 of the distance provided with the inner cylinder claw 13. The relationship between the distance P1 which is the distance between the inner cylinder claws 13 and the distance P3 which is the distance between the outer cylinder first claw 30a and the outer cylinder second claw 31a in the left-right direction (insertion direction) is as follows (3). ).

P3 = P1 × 3/2 ... (3)

Further, the distance from the outer cylinder second claw 31a to the inner cylinder second claw 13b, which is the next inner cylinder claw 13 in the insertion direction, is P1. On the other hand, the distance P4 from the outer cylinder first claw 30a to the inner cylinder fourth claw 13d, which is the next inner cylinder claw 13 in the insertion direction, can be expressed by the following equation (4).

P4 = P3-P1
= P1 / 2 ... (4)

When the outer cylinder 11 is inserted into the inner cylinder 12 from the state of FIG. 7 (a) (the outer cylinder 11 moves in the insertion direction), the outer cylinder 11 and the inner cylinder 12 are in the state of FIG. 7 (b). Move to. That is, the hook of the outer cylinder second claw 31a to the inner cylinder third claw 13c is released, and the outer cylinder first claw 31a hooks the inner cylinder second claw 13b before the outer cylinder second claw 31a is hooked. 30a hooks the inner cylinder fourth claw 13d. This is because the outer cylinder 11 needs to move a distance P1 in order for the outer cylinder second claw 31a to hook the inner cylinder third claw 13c, whereas the outer cylinder first claw 30a is the inner cylinder first. This is because, in order to hook the four claws 13d, the outer cylinder 11 only needs to move a distance half the distance P1 (that is, the distance P4).

Similarly, when the outer cylinder 11 is further inserted into the inner cylinder 12 (the outer cylinder 11 moves in the insertion direction), the hook of the outer cylinder 1st claw 30a of the outer cylinder 11 to the inner cylinder 4th claw 13d is released. Therefore, the outer cylinder second claw 31a hooks the inner cylinder second claw 13b before the outer cylinder first claw 30a hooks the inner cylinder third claw 13c. This is because the outer cylinder first claw 30a needs to move the distance P1 in order to hook the inner cylinder third claw 13c, whereas the outer cylinder second claw 31a moves the inner cylinder second claw 13b. This is because it is only necessary to move a distance half the distance P1 (that is, the distance P4) in order to stop the hook. Similarly, thereafter, the outer cylinder 11 hooks the inner cylinder 12 while changing the combination of the inner cylinder claw 13 on which the outer cylinder first claw 30a and the outer cylinder second claw 31a are hooked, and the outer cylinder 11 hooks the inner cylinder 12 at a distance P1. Move in the insertion direction by a distance of 1/2 of.

In the cord bushing 10 of the second embodiment, the distance between the outer cylinder first claw 30 and the outer cylinder second claw 31 in the insertion direction is widened to 3/2 times the distance provided by the inner cylinder claw 13. Instead, the distance that the outer cylinder 11 moves can be halved from the distance P1 as in the first embodiment. As a result, the moving distance in which the outer cylinder 11 moves stepwise can be shortened without narrowing the distance between the outer cylinder first claw 30 and the outer cylinder second claw 31 in the insertion direction or the distance between the inner cylinder claws 13. can. That is, the outer cylinder 11 hooks the inner cylinder 12 while moving toward the flange 14 at half the interval of the inner cylinder claw 13. Therefore, when the cord bushing 10 is industrially processed, the gap between the outer cylinder 11 and the wall surface on the first space side and the second space side are not required regardless of the wall thickness, even if a high degree of accuracy is not required. The wall can be sandwiched by reducing the gap between the wall surface and the inner cylinder 12. Therefore, there is an effect that the occurrence of defective products can be reduced and the production efficiency of the cord bushing 10 can be increased.

In addition, the code bushing 10 in the second embodiment has the same effect as the code bushing 10 in the first embodiment based on the same components as the code bushing 10 in the first embodiment.

Next, the code bushing 10 in the third embodiment will be described with reference to FIG. In the cord bushing 10 of the first embodiment, two pairs of claws (outer cylinder first claw 30 and outer cylinder second claw 31) are provided on the outer cylinder 11 at an interval of 1/2 of the interval provided with the inner cylinder claw 13. The case was explained. On the other hand, in the cord bushing 10 in the third embodiment, the outer cylinder 11 is provided with three pairs of claws (outer cylinder first claw 40, outer cylinder second claw 41, outer cylinder third claw 42), and the outer cylinder first. The distance between the 1 claw 40 and the outer cylinder 2nd claw 41 in the insertion direction and the distance between the outer cylinder 2nd claw 41 and the outer cylinder 3rd claw 42 in the insertion direction are 1/1 of the distance provided with the inner cylinder claw 13, respectively. It is provided at intervals of 3.

Hereinafter, the code bushing 10 of the third embodiment will be described focusing on the differences from the code bushing 10 of the first embodiment, and the same reference numerals will be given to the same configurations as the code bushing 10 of the first embodiment. And the explanation is omitted.

FIG. 8A is a diagram schematically showing a state in which the outer cylinder third claw 42a of the cord bushing 10 in the third embodiment is hooked on the inner cylinder 12, and FIG. 8B is a diagram. FIG. 8C is a diagram schematically showing a state in which the outer cylinder second claw 41a hooks the inner cylinder 12, and FIG. 8C shows the outer cylinder first claw 40a hooking the inner cylinder 12. It is a figure which showed the state schematically. In these figures, the outer cylinder first claw 40a, the outer cylinder second claw 41a, and the outer cylinder third claw 42a are in the left-right direction (direction from the left end of the inner cylinder 12 toward the flange 14) with respect to the inner cylinder claw 13. ) Is schematically shown, and the inner cylinder 12 and the outer cylinder second claw 41a are shown by a solid line, and the outer cylinder first claw 40a and the outer cylinder first claw at that time are shown by a solid line. The state with the three claws 42a is shown by an imaginary line.

As shown in FIG. 8A, the outer cylinder first claw 40a, the outer cylinder second claw 41a, and the outer cylinder third claw 42a are provided at different positions in the outer cylinder 11 in the left-right direction, and are provided on the leftmost side. Is provided with an outer cylinder first claw 40a, an outer cylinder second claw 41a in the middle, and an outer cylinder third claw 42a on the far right.

Although not shown, the outer cylinder 11 includes a pair of outer cylinder first claws 40a and 40b at point-symmetrical positions with respect to the center of the circular outer cylinder 11 circle (a pair of outer cylinder first claws 40a and 40b). One claw is called the outer cylinder first claw 40). The outer cylinder 11 includes a pair of outer cylinder second claws 41a and 41b at positions displaced clockwise from the outer cylinder first claws 40a and 40b by about 60 degrees (a pair of outer cylinder second claws 41a and 41b). Is called the outer cylinder second claw 41). Further, the outer cylinder 11 includes outer cylinder third claws 42a and 42b at positions displaced clockwise from the outer cylinder second claws 41a and 41b by about 60 degrees (a pair of outer cylinder third claws are provided on the outer cylinder first). 3 claws 42).

In FIG. 8A, the outer cylinder third claw 42a hooks the inner cylinder fourth claw 13d. At this time, neither the outer cylinder first claw 40a nor the outer cylinder second claw 41a is hooked on the inner cylinder claw 13. Further, the distance between the outer cylinder first claw 40a and the outer cylinder second claw 41a in the insertion direction and the distance between the outer cylinder second claw 41a and the outer cylinder third claw 42a in the insertion direction are a distance P5. The relationship between the distance P1 and the distance P5, which are the intervals at which the inner cylinder claws 13 are provided, can be expressed by the following equation (5).

P5 = P1 x 1/3 ... (5)

When the outer cylinder 11 is inserted into the inner cylinder 12 from the state of FIG. 8 (a), the outer cylinder 11 and the inner cylinder 12 shift to the state of FIG. 8 (b). That is, the hook of the outer cylinder third claw 42a to the inner cylinder fourth claw 13d is released, and this time, the outer cylinder second claw 41a hooks the inner cylinder fourth claw 13d. At this time, the outer cylinder 11 can be moved toward the flange 14 by a distance P5 (1/3 of the distance provided with the inner cylinder claw 13).

When the inner cylinder 12 is inserted into the outer cylinder 11 from the state of FIG. 8 (b), the outer cylinder 11 and the inner cylinder 12 shift to the state of FIG. 8 (c). That is, the hook of the outer cylinder second claw 41a to the inner cylinder fourth claw 13d is released, and this time, the outer cylinder first claw 40a hooks the inner cylinder fourth claw 13d. At this time, the outer cylinder 11 can be moved toward the flange 14 by a distance P5 (1/3 of the distance provided with the inner cylinder claw 13).

Similarly, when the outer cylinder 11 is further inserted into the inner cylinder 12 (the outer cylinder 11 moves in the insertion direction), the hook of the outer cylinder 1st claw 40a of the outer cylinder 11 to the inner cylinder 4th claw 13d is released. Therefore, the outer cylinder third claw 42a hooks the inner cylinder third claw 13c before the outer cylinder first claw 40a and the outer cylinder second claw 41a hook the inner cylinder third claw 13c. This is because the outer cylinder first claw 40a needs to move a distance P1 in order to hook the inner cylinder third claw 13c, and the outer cylinder second claw 41a hooks the inner cylinder third claw 13c. It is necessary to move the distance P1 × 2/3, whereas the outer cylinder third claw 42a moves a distance of 1/3 of the distance P1 in order to hook the inner cylinder third claw 13c. This is because all you have to do is do it. Similarly, thereafter, the outer cylinder 11 hooks the inner cylinder 12 while changing the combination of the inner cylinder claw 13 on which the outer cylinder first claw 40a, the outer cylinder second claw 41a, and the outer cylinder third claw 42a are hooked. , The outer cylinder 11 moves in the insertion direction by a distance of 1/3 of the distance P1.

As a result, the outer cylinder 11 can be moved to the flange 14 side little by little. Therefore, the outer cylinder 11 and the first generated when the contact surface 32 of the outer cylinder 11 and the contact surface 17 of the inner cylinder 12 are brought as close as possible to sandwich the wall between the outer cylinder 11 and the inner cylinder 12. There is an effect that the gap between the wall surface on the one space side and the gap between the inner cylinder 12 and the wall surface on the second space side can be made extremely small.

In addition, the code bushing 10 in the third embodiment has the same effect as the code bushing 10 in the first embodiment based on the same components as the code bushing 10 in the first embodiment.

Next, the code bushing 10 in the fourth embodiment will be described with reference to FIG. In the cord bushing 10 of the first embodiment, two pairs of claws (outer cylinder first claw 30 and outer cylinder second claw 31) are provided on the outer cylinder 11 at an interval of 1/2 of the interval provided with the inner cylinder claw 13. The case was explained. On the other hand, in the cord bushing 10 in the fourth embodiment, the outer cylinder 11 is provided with three pairs of claws (outer cylinder first claw 40, outer cylinder second claw 41, outer cylinder third claw 42), and the outer cylinder first. The distance between the 1st claw 40 and the outer cylinder 2nd claw 41 in the insertion direction and the distance between the outer cylinder 2nd claw 41 and the outer cylinder 3rd claw 42 in the insertion direction are 2 / of the distance where the inner cylinder claw 13 is provided. It is provided at intervals of 3.

Hereinafter, the code bushing 10 of the fourth embodiment will be described focusing on the differences from the code bushing 10 of the first embodiment, and the same reference numerals will be given to the same configurations as the code bushing 10 of the first embodiment. And the explanation is omitted.

FIG. 9A is a diagram schematically showing a state in which the third claw 42a of the outer cylinder of the cord bushing 10 in the fourth embodiment hooks the inner cylinder 12, and FIG. 9B is a diagram. FIG. 9C is a diagram schematically showing a state in which the outer cylinder second claw 41a hooks the inner cylinder 12, and FIG. 9C shows the outer cylinder first claw 40a hooking the inner cylinder 12. It is a figure which showed the state schematically. In these figures, the outer cylinder first claw 40a, the outer cylinder second claw 41a, and the outer cylinder third claw 42a are in the left-right direction (direction from the left end of the inner cylinder 12 toward the flange 14) with respect to the inner cylinder claw 13. ) Is schematically shown, and the inner cylinder 12 and the outer cylinder second claw 41a are shown by a solid line, and the outer cylinder first claw 40a and the outer cylinder first claw at that time are shown by a solid line. The state with the three claws 42a is shown by an imaginary line.

As shown in FIG. 9A, the outer cylinder first claw 40a, the outer cylinder second claw 41a, and the outer cylinder third claw 42a are provided at different positions in the outer cylinder 11 in the left-right direction. The outer cylinder first claw 40a is provided, the outer cylinder second claw 41a is provided in the center, and the outer cylinder third claw 42a is provided on the far right.

Although not shown, the outer cylinder 11 includes a pair of outer cylinder first claws 40a and 40b at points symmetrical with respect to the center of the circular outer cylinder 11 (a pair of outer cylinders). The first claw is called the outer cylinder first claw 40). The outer cylinder 11 includes a pair of outer cylinder second claws 41a and 41b at positions displaced clockwise from the outer cylinder first claws 40a and 40b by about 60 degrees (a pair of outer cylinder second claws 41a and 41b). Is called the outer cylinder second claw 41). Further, the outer cylinder 11 includes outer cylinder third claws 42a and 42b at positions displaced clockwise from the outer cylinder second claws 41a and 41b by about 60 degrees (a pair of outer cylinder third claws are provided on the outer cylinder first). 3 claws 42).

In FIG. 9A, the outer cylinder third claw 42a hooks the inner cylinder third claw 13c. At this time, neither the outer cylinder first claw 40a nor the outer cylinder second claw 41a is hooked on the inner cylinder claw 13. Further, the distance between the outer cylinder first claw 40a and the outer cylinder second claw 41a in the insertion direction and the distance between the outer cylinder second claw 41a and the outer cylinder third claw 42a in the insertion direction are a distance P6. The relationship between the distance P1 and the distance P6, which are the intervals at which the inner cylinder claws 13 are provided, can be expressed by the following equation (6).

P6 = P1 x 2/3 ... (6)

When the outer cylinder 11 is inserted into the inner cylinder 12 from the state of FIG. 9 (a), the outer cylinder 11 and the inner cylinder 12 shift to the state of FIG. 9 (b). That is, the hook of the outer cylinder third claw 42a to the inner cylinder third claw 13c is released, and this time, the outer cylinder first claw 40a hooks the inner cylinder fourth claw 13d. At this time, the outer cylinder 11 moves toward the flange 14 by a distance P7 (1/3 of the distance provided with the inner cylinder claw 13).

When the inner cylinder 12 is inserted into the outer cylinder 11 from the state of FIG. 9 (b), the outer cylinder 11 and the inner cylinder 12 shift to the state of FIG. 9 (c). That is, the hook of the outer cylinder first claw 40a to the inner cylinder fourth claw 13d is released, and this time, the outer cylinder second claw 41a hooks the inner cylinder third claw 13c. At this time, the outer cylinder 11 moves toward the flange 14 by the distance P7.

Similarly, when the outer cylinder 11 is further inserted into the inner cylinder 12 (the outer cylinder 11 moves in the insertion direction), the hook of the outer cylinder 2nd claw 41a of the outer cylinder 11 to the inner cylinder 3rd claw 13c is released. The outer cylinder third claw 42a is attached to the inner cylinder second before the outer cylinder first claw 40a and the outer cylinder second claw 41a hook the inner cylinder third claw 13c and the inner cylinder second claw 13b. Hook the claw 13b. This is because the outer cylinder first claw 40a needs to move a distance P1 × 2/3 in order to hook the inner cylinder third claw 13c, and the outer cylinder second claw 41a moves the inner cylinder second claw 13b. While it is necessary to move the distance P1 in order to hook, the outer cylinder third claw 42a moves a distance of 1/3 of the distance P1 in order to hook the inner cylinder second claw 13b. This is because all you have to do is do it. Similarly, thereafter, the outer cylinder 11 hooks the inner cylinder 12 while changing the combination of the inner cylinder claw 13 on which the outer cylinder first claw 40a, the outer cylinder second claw 41a, and the outer cylinder third claw 42a are hooked. , The outer cylinder 11 moves in the insertion direction by a distance of 1/3 of the distance P1.

That is, in the fourth embodiment, although the distance between the outer cylinder first claw 40, the outer cylinder second claw 41, and the outer cylinder third claw 42 in the insertion direction is wider than that in the third embodiment, the outer cylinder 11 The distance traveled by can be set to 1/3 of P1 as in the third embodiment. As a result, the outer cylinder 11 moves stepwise without narrowing the distance between the outer cylinder first claw 40, the outer cylinder second claw 41, and the outer cylinder third claw 42 in the insertion direction and the distance between the inner cylinder claws 13. The distance can be shortened. Therefore, when the cord bushing 10 is industrially processed, the gap between the outer cylinder 11 and the wall surface on the first space side and the second space side are not required regardless of the wall thickness, even if a high degree of accuracy is not required. The wall can be sandwiched by reducing the gap between the wall surface and the inner cylinder 12. Therefore, there is an effect that the occurrence of defective products can be reduced and the production efficiency of the cord bushing 10 can be increased.

Although the present invention has been described above based on the embodiments, the present invention is not limited to the above embodiments, and it is easy to make various improvements and modifications within a range that does not deviate from the gist of the present invention. It can be inferred. For example, each embodiment may be configured by modifying the embodiment by exchanging with a part or a plurality of parts of the configuration of the other embodiment. Further, the numerical values given in each of the above embodiments are examples, and it is naturally possible to adopt other numerical values.

In each of the above embodiments, by supporting the contact surface 32 of the outer cylinder 11 with the support member 34, it is possible to make a bullet contact with the wall surface on the first space side, but the present invention is not limited to this. For example, instead of the contact surface 32 of the outer cylinder 11, the contact surface 17 of the inner cylinder 12 may be supported by an elastically deforming member so that it can be in bullet contact with the wall surface on the first space side. .. Further, both the outer cylinder 11 and the inner cylinder 12 may be configured so as to be in bullet contact with the wall surface.

In each of the above embodiments, the inner cylinder 12 is provided with eight inner cylinder claws 13, and the outer cylinder 11 is provided with two or three pairs of outer cylinder claws, but the number of claws is not limited thereto. .. For example, when used on a thick wall, the length of the cylinder 16 of the inner cylinder 12 in the left-right direction may be increased to increase the number of inner cylinder claws 13. Further, the number of claws of the inner cylinder 12 and the outer cylinder 11 may be exchanged. For example, the outer cylinder 11 may be provided with eight pairs of claws, and the inner cylinder 12 may be provided with two claws.

In each of the above embodiments, the inner cylinder claw 13 is provided in an annular shape on the cylinder 16. Further, the pair of outer cylinder first claws 30 and the pair of outer cylinder second claws 31 are provided so as to project from the inner peripheral surface of the outer cylinder 11, but the shape of these claws is limited to this. It's not something. It is not necessary to pair the outer cylinder claws, and for example, the outer cylinder 11 may be provided in an annular shape on the inner peripheral surface.

In each of the above embodiments, the means for releasing the hooked state is not provided, but for example, a cut may be provided in a part of the circumference of the outer cylinder 11 so that the inner diameter of the outer cylinder 11 can be changed. It may be configured so that the outer cylinder 11 can be disengaged from the inner cylinder 12 by increasing the inner diameter.

In each of the above embodiments, a pair of claws (outer cylinder first claw, outer cylinder second claw, outer cylinder third claw) are provided so as to be point-symmetric with respect to the center of the outer cylinder 11. It is not limited to. For example, the number of claws may be at least one. However, it is preferable that there are a plurality of claws. Further, when the number of claws is a plurality, they may be arranged on concentric circles of the circles of the outer cylinder 11. At this time, it is more preferable to arrange a plurality of claws at equal intervals on the concentric circles of the outer cylinder 11.

In each of the above embodiments, the inner cylinder claw 13 of the inner cylinder 12 is provided in an annular shape, but the present invention is not limited to this. For example, even if the claws are provided only on the portion where the outer cylinder first claw 30, the outer cylinder second claw 31, the outer cylinder first claw 40, the outer cylinder second claw 41, and the outer cylinder third claw 42 are hooked. good. In this case, when the outer cylinder 11 is rotated in the circumferential direction, the outer cylinder first claw 30, the outer cylinder second claw 31, the outer cylinder first claw 40, the outer cylinder second claw 41, and the outer cylinder third claw 42 There may be a configuration in which there is a position where none of the above hooks the inner cylinder claw 13. With such a configuration, the outer cylinder 11 can keep the inner cylinder 12 hooked, but when it is desired to release the hooked state, the outer cylinder 11 can be simply rotated in the circumferential direction. There is an effect that the outer cylinder 11 can be easily removed from the inner cylinder 12.

In each of the above embodiments, an example in which the outer cylinder 11 is arranged on the left side of the wall and the inner cylinder 12 is arranged on the right side of the wall is shown, but the present invention is not limited to this. For example, the outer cylinder 11 may be arranged on the right side of the wall, and the inner cylinder 12 may be arranged on the left side of the wall. In that case, the space on the right side of the wall becomes the first space, and the space on the left side of the wall becomes the second space.

10 Cord bushing 11 Outer cylinder 12 Inner cylinder 13 Inner cylinder claw (second hooking means)
17 Contact surface (second contact means)
30 Outer cylinder 1st claw (part of the 1st contact means)
31 Outer cylinder second claw (part of the first contact means)
32 Contact surface (first contact means)
34 Support member (elastic means)

Claims (4)

A cord bushing that is attached in a tubular shape to a hole provided in a wall, a cord is passed through the cylinder, and the cord is pulled out between a first space and a second space partitioned by the wall.
An outer cylinder having a first contact means that contacts one surface of the wall,
It has a second contact means that contacts the other surface of the wall, and is formed so as to be insertable into the outer cylinder so that the wall is sandwiched between the first contact means and the second contact means. With an inner cylinder,
The outer cylinder includes a plurality of first hooking means.
The inner cylinder is paired with one of the first hooking means, and includes a plurality of second hooking means capable of hooking the outer cylinder and the inner cylinder in a direction opposite to the insertion direction.
The cord bushing changes the combination of the first hooking means and the second hooking means for hooking while inserting the inner cylinder relative to the outer cylinder, thereby changing the first hooking means. The wall can be sandwiched by narrowing the distance between the contact means and the second contact means.
When at least a pair of the first hooking means and the second hooking means are hooked, the second hooking means and the non-hooking first hooking means exist, and the non-hooking first The distance from the hooking means to the first hooking means and the second hooking means on the side of the second contacting means that can be hooked is the distance from the first hooking means that has been hooked to the first hooking means. The first hook so that there is at least one non-hook first hook means that is shorter than the distance to the non-hook second hook means on the side of the second contact means that can be hooked. A cord bushing characterized in that a stopping means and a second hooking means are provided. At least one of the first contact means and the second contact means includes elastic means.
Its resilient means, the code of claim 1, wherein the by said second contact means and the first contact means is an elastic deformation and resulting shall in contact with the wall when sandwiching the wall Bushing. The inner cylinder is
It is possible to penetrate the hole provided in the wall from the second space.
When the second contact means is in contact with the wall on the second space side, the second hooking means is configured to appear on the first space side.
The outer cylinder is
The inner cylinder is relatively inserted on the first space side.
Claim 1 is characterized in that the wall is sandwiched between the second contact means in contact with the wall on the second space side and the first contact means in contact with the wall on the first space side. Or the code bushing described in 2. The first hooking means is
The code bushing according to any one of claims 1 to 3, wherein the other first hooking means is configured so as not to exist on a straight line in the insertion direction passing through the first hooking means. ..

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